Web Analytics
Privacy Policy Cookie Policy Terms and Conditions SPARC-HOWTO.: SMP. Next Previous Contents

21. SMP.

Ouaich, SMP is supported, and I am sure that ROSS's dual CPU modules are supported as you can see by yourself:



piou@ywing:~ > cat /proc/cpuinfo 
cpu             : ROSS HyperSparc RT625 or RT626
fpu             : ROSS HyperSparc combined IU/FPU
promlib         : Version 3 Revision 2
prom            : 2.25
type            : sun4m
ncpus probed    : 2
ncpus active    : 2
Cpu0Bogo        : 125.33
Cpu1Bogo        : 125.33
MMU type        : ROSS HyperSparc
invall          : 0
invmm           : 0
invrnge         : 0
invpg           : 0
contexts        : 4096
CPU0            : online
CPU1            : online
piou@ywing:~ > 

The SparcStation 10 and SparcStations 20 are SMP capable computers and according to the FAQABOSS the following combinations are known to work :

And, as stated earlier, CPU modules in SparcStations 10 and can run a different clock speeds, the following ones __SHOULD__ work:

How does it performs? Well, it is fast, really fast. Some of the java Demos can run faster on a dual HyperSparc 125Mhz 128MB ( ywing ) than on a dual celeron BP6 433@433Mhz 192MB ( calimero ). The same applies for the Gimp. When it comes to compiling calimero runs faster than ywing. Both computers running 2.2.16 kernel and calimero's hard disk subsystem is full SCSI.

One important detail when you plan to have different CPU modules in your computer is to have the same kind of modules, you cannot mix SuperSparc and HyperSparc for example, but you can have an odd number of CPUs, for example 3. They are said to be able to run modules at different clock speed as written in this article form AcesHardware , but I have not witnessed it.

ywing has been upgraded to quad-CPU. You can read the kernel's message:


cpu             : ROSS HyperSparc RT625 or RT626
fpu             : ROSS HyperSparc combined IU/FPU
promlib         : Version 3 Revision 2
prom            : 2.25
type            : sun4m
ncpus probed    : 4
ncpus active    : 4
Cpu0Bogo        : 125.33
Cpu1Bogo        : 125.33
Cpu2Bogo        : 125.33
Cpu3Bogo        : 125.33
MMU type        : ROSS HyperSparc
invall          : 0
invmm           : 0
invrnge         : 0
invpg           : 0
contexts        : 4096
CPU0            : online
CPU1            : online
CPU2            : online
CPU3            : online

and its main memory is now 256MB:


total:    used:    free:  shared: buffers:  cached:
Mem:  263028736 29114368 233914368 22958080  1695744 12779520
Swap: 133849088        0 133849088
MemTotal:    256864 kB
MemFree:     228432 kB
MemShared:    22420 kB
Buffers:       1656 kB
Cached:       12480 kB
BigTotal:         0 kB
BigFree:          0 kB
SwapTotal:   130712 kB
SwapFree:    130712 kB

So I have performed an empirical proftpd compilation test using the make -JN. The results are:


with make
real    3m27.466s
user    3m15.670s
sys     0m12.030s

with make -j2

real    1m52.670s
user    3m27.210s
sys     0m15.310s

with make -j3

real    1m22.560s
user    3m43.910s
sys     0m18.070s

with make -j4
real    1m13.582s
user    4m2.200s
sys     0m22.830s

with make -j5
real    1m13.445s
user    4m4.060s
sys     0m22.640s

with make -j8

real    1m15.550s
user    4m1.840s
sys     0m22.960s

with make -j 10
real    1m20.091s
user    4m2.440s
sys     0m22.170s

As expected the best results are with make -j5 ( one instance per CPU + one ready to enter when a cache miss occurs ); then N increasing the results are starting to worsen.

As a conclusion, those sun4m SMP systems will be very interesting when Gimp 2.0 will be available because of multitreading and paralelization of algorithms.

If you want to learn more about SMP and Linux you can read the SMP-HOWTO http://www.tldp.org/HOWTO/SMP-HOWTO.html


Next Previous Contents